Modified exendins and uses thereof
The present invention discloses a modified exendin or pharmaceutically acceptable salts thereof, wherein the modified exendin comprises an amino acid sequence having at least 90% sequence identity to SEQ ID No. 17 and the amino acid sequence has a higher stability than the non-modified exendin of SEQ ID No. 4. These compounds are useful in treating type 2 diabetes as GLP-1 receptor agonists.
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This application is a Continuation in Part of U.S. patent application Ser. No. 11/813,917, filed Jul. 13, 2007, now issued as U.S. Pat. No. 8,097,586, which is a National Stage Entry of PCT/CN2006/000029 filed Jan. 10, 2006, which claims priority of Chinese Application No. 200510038102.3 filed Jan. 14, 2005.
FIELD OF THE INVENTIONThe present invention relates to long-lasting exendins and pharmaceutical acceptable salts thereof. To be more particular, the present invention relates to pegylated exendins and pharmaceutical acceptable salts thereof, and preparation method thereof as well as their uses in preventing and treating type 2 diabetes by regulating the blood glucose level due to the stimulation of the secretion of insulin from β-cell induced by the Glucagon-like peptide 1 (GLP-1) receptor acting with said compounds.
BACKGROUND ARTRecently, accompanying with the increased living standard, modernization of living style and aging of society, incidence of diabetes is also kept increasing on a yearly basic all over the world, of which the situation is especially obvious in developing countries. Diabetes has become the third major chronic non-communicable disease next to malignant tumors, cardio-cerebrovascular diseases, and constituted the major causes to mortality and disability. As reported in WHO report of 1997 that by that time there are 135 millions of people suffering from diabetes and 175 millions are expected to be reached by 2000. In China, a recent report shows that incidence of diabetes in the population of age over 20 is 3.21%. A preliminary estimation shows that there are at least 20 millions of diabetes patients in China nowadays, in which over 95% of them are type 2 diabetes patients. From 1987 to 1992, the annual outlay for direct or indirect uses in diabetes in United State increased from 1 billion to 92 billion US Dollars. In China, the outlay for treatment of diabetes is also increasing at an incredible speed. According to a related statistical analysis reported in 1993 that up to 2.2 billions dollars were spend on the treatment of diabetes at that time, in which neither the cost for the treatment of diabetes syndrome, outlay for out-hospital treatments and health care, nor indirect loss in social economy were included.
Type 2 diabetes can be controlled by moderation of dietary intake, exercise and regulation of the blood-glucose level with medication. Commonly employed medication includes insulin, sulphonylurea, biguanide as well as Glitazone compounds. These compounds help only in promoting the blood-glucose level back to the normal level while unable to recover the impairments, especially to kidney, cardiovascular system, optical or nervous system caused by diabetes syndrome. These syndromes are closely associated with the increased mortality caused by diabetes. The major side effects inherent in the first generation of diabetic medications include hypoglycemia, increase in body-weight and dropsy. The acting mechanisms of these medications maybe different, however, none of them is able to protect the insulin-secreting β-cell, thereby, the in vivo blood glucose metabolism and incretion regulation cannot be maintained in normal condition. In most cases, consecutive use of a single medicine renders its effectiveness reduced gradually, which gives rise to the application of drug-combination therapy. Since diabetes patients take blood pressure-lowering and cholesterol reducing drugs simultaneously during treatment, the long-term effect of this treatment is not stable. Therefore, development of new medications to cooperate with current medications for the regulation of blood glucose level, and to achieve the objects in protecting and recovering the functionality of β-cell as well as adjusting incretion in response to food intake would result in a great improvement in diabetic treatment.
Investigation of Glucagon-like peptide-1 (GLP-1) receptor agonist is a likely topic. Investigation and development in this field may open a new chapter in the treatment of type 2 diabetes. Glucagon-like peptide-1 was firstly discovered in 1984, which is a kind of intestinal secretion hormones. If type 2 diabetics were injected with this hormone, their blood glucose level can be adjusted to a normal level (Nathan, D M, et al. Diabetes Care 1992; 15:270-6; Zander, M, et al. Lancet 2002; 359:824-30). It was reported that action of Glucagon-like peptide and receptor agonist thereof is mainly caused by insulin secretion induced by activating the Glucagon-like peptide 1 receptor on the surface of the pancreas β-cell. Since this effect depends on the in vivo blood glucose level, fatal hypoglycemic shock caused by the extremely low blood glucose level even in the presence of Glucagon-like peptide and receptor agonist thereof would not occur like the traditional medication does. More particularly, when the in vivo blood glucose level is higher than 6 mmol/L, GLP-1 remarkably stimulates secretion of insulin, whereas when the in vivo blood glucose level reaches the normal level, the stimulation discontinue. Also, this type of agonist stimulates the proliferation of pancreas β-cell of rodent (rat) and also enhances the action of β-cell tissue. The function that allows the recovery of the pancreas β-cell opens up prospects for the treatment of type 2 diabetes by at least delaying the onset of type 1 diabetes from type 2 diabetes. Meanwhile the Glucagon-like peptide and receptor agonist thereof is able to inhibit the secretion of glucagon, and thereby make it possible to reduce the output of blood glucose from liver. More importantly, this type of agonist reduces the dietary intake by inhibiting the gastrointestinal peristalsis and gastric emptying, thereby reduces the body weight and also helps in controlling the body weight of type 2 diabetics.
BRIEF SUMMARY OF THE INVENTIONThe objective of the present invention is to provide long-lasting pegylated exendins and pharmaceutical acceptable salts thereof. They can induce the secretion of insulin and decrease the blood glucose level by activating the Glucagon-like peptide 1 (GLP-1) receptor and thereby useful in treating and preventing type 2 diabetes. This type of compounds have a long retention time in vivo and exhibits a prolonged action therein.
The prolonged retention is not only due to the delay of renal excretion caused by pegylation, but also due to the improved in vivo enzymatic and chemical stability of the peptide backbone resulted from the pegylation. Pegylation ensures the long-lasting effect of these compounds and thereby reduces the injection frequency to patients, and patients may get the benefits of improved quality and effectiveness of such therapy.
More particularly, the present invention relates to, but is not limited to all pegylated polypeptide precursors listed in the sequence table, and compounds modified with polyethylene glycol with various molecular weights, and pharmaceutical acceptable salts thereof.
Another objective of the present invention is to provide a method for the preparation of long-lasting pegylated exendins and pharmaceutical acceptable salts thereof.
Still another objective of the present invention is to provide the use of the long-lasting exendins and/or pharmaceutical acceptable salts thereof as a Glucagon-like peptide 1 (GLP-1) receptor agonist in treating and preventing type 2 diabetes.
The following technical solutions achieve the objectives of the present invention. The present invention relates to exendins and pharmaceutical acceptable salts thereof whose peptide backbone possesses optimized in vivo enzymatic and chemical stability. Particularly, the present invention relates to exendins comprising (A) amino acid sequences of SEQ ID Nos 4 to 141, (B) amino acid sequences substantially identical to those of SEQ ID Nos. 4 to 141.
In one aspect, the present invention provides a modified exendin or pharmaceutically acceptable salts thereof, wherein the modified exendin comprises an amino acid sequence having at least 90% sequence identity to SEQ ID No. 17 wherein the amino acid sequence has a higher stability than the non-modified exendin of SEQ ID No. 4.
“Sequence identity” means the fraction of two aligned sequences being compared that are identical. Sequence alignment and calculation of % sequence identity can be performed using the BLAST program (Basic Local Alignment Search Tool, available online on the webpage of the National Center for Biotechnology Information at http://www.ncbi.nlm.nih.gov) using the blastp algorithm for a standard protein blast under default parameters (word size 3, SEG filter “on”, expect value 10, scoring matrix BLOSUM62), on a comparison window including the whole amino acid sequences.
The modified exendin or pharmaceutically acceptable salts thereof may consist essentially of an amino acid sequence having at least 90% sequence identity to SEQ ID No. 17 wherein the sequence comprises further aminoacids at the N-terminal or C-terminal end, for example, without limitation, a modified C-terminal end such as a pegylated C-terminal end with added aminoacids X40-49 as described below, or minor changes such as insertions of aminoacids, provided the resulting modified exendin retains its characteristics and increased stability.
In an embodiment, the modified exendin in accordance to the present invention comprises an amino acid sequence having at least 90% sequence identity to SEQ ID No. 17, for example at least 91%, at least 92%, at least 93%, at least 94%, at least 95%, at least 96%, at least 97%, at least 98% or at least 99% sequence identity to SEQ ID No. 17.
The modified exendin comprising an amino acid sequence having at least 90% sequence identity to SEQ ID No. 17 may be made on the basis of similarity in polarity, charge, solubility, hydrophobicity, hydrophilicity, and/or the amphipathic nature of the residues as long as the activity of the exendin is retained and the stability is increased compared to exendin-4.
In an embodiment, the amino acid of the modified exendin at position 2 with reference to the position numbering of SEQ ID No. 17 is D-Alanine.
In an embodiment, the modified exendin may comprise an amino acid sequence having one or more substitutions at positions selected from positions 14 and 28 with reference to the position numbering of SEQ ID No. 17.
In an embodiment, the amino acid of the modified exendin at position 2 with reference to the position numbering of SEQ ID No. 17 is D-Alanine, and the modified exendin comprises one or more substitutions at positions selected from positions 14 and 28 with reference to the position numbering of SEQ ID No. 17.
In an embodiment, the modified exendin may comprise an amino acid sequence selected from the group consisting of any one of SEQ ID Nos. 17-141. In such an embodiment, the modified exendin may comprise an amino acid sequence selected from any one of SEQ ID Nos. 17-30, all of which comprise D-Alanine at position 2 with reference to the position numbering of SEQ ID No. 17. In a preferred embodiment, the modified exendin may comprise an amino acid sequence selected from any one of SEQ ID Nos. 59-86 and 114-127, all of which comprises D-Alanine at position 2 and a further substitution at position 14 or 28, with reference to the position numbering of SEQ ID No. 17. In a more preferred embodiment, the modified exendin may comprise an amino acid sequence selected from any one of SEQ ID Nos. 87-99, 100-113 and 128-141, all of which comprise D-Alanine at position 2 and further substitutions at position 14 and 28, with reference to the position numbering of SEQ ID No. 17.
The modified exendin may comprise polyethylene glycol for modification, said polyethylene glycol may have a molecular weight of 20,000 to 60,000 daltons, for example, without limitation, 40,000 daltons.
The polyethylene glycol may be connected to a regiospecific group at the carboxyl terminal end of the amino acid sequence of the modified exendin, for example, without limitation, C-terminal mercapto-containing amino acids (such as cysteine) may be pegylated.
The modified exendin may comprise the following consensus sequence,
which differs from the exendin-4 sequence
in at least one substitution in positions 2, 14, 27, 28 or 39,
wherein X2, X14, X27, X28 and X39 are substituted amino acids,
wherein X39-49 is a singly or multiply pegylated sequence of the formula Cys(39))-(Xaa)n−1-Cys(n+39), with n being the number of amino acids added to the C-terminal end, and n is 0-10;
wherein X2, X14, the pair of X27-28 and X39 may be independently selected for substitution,
wherein X2 is selected from G and dA,
wherein X14 is selected from M and Nle,
wherein the amino acid pair X27-28 is selected from KN, KQ, QK, and VK,
wherein X39 is selected from S, C, C(AM), K*, and C-PEG,
wherein X39-49 is a multiply pegylated amino acid sequence optionally selected from C-PEGC-PEG, C-PEGXaaC-PEG, C-PEGXaaXaaC-PEG, C-PEGXaaXaaXaaC-PEG, and C-PEGXaaC-PEGXaaC-PEG;
and wherein dA is D-alanine, Nle is norleucine, C(AM) is a iodacetamide protected mercapto-group of cysteine, K* is lysine with a modified side-chain, including mercaptopropionic acid on the amino group of the side chain of lysine, C-PEG is cysteine pegylated with PEG20-60K, and Xaa is any aminoacid.
It is provided a modified exendin as described in the substituted consensus sequence above, wherein the substituted consensus sequence is selected from a sequence wherein X2 is dA; a sequence wherein X14 is Nle; a sequence wherein X28 is Q; a sequence wherein X28 is K; a sequence wherein X14 is Nle and X28 is Q; a sequence wherein X14 is Nle and X28 is K; a sequence wherein X2 is dA and X14 is Nle; a sequence wherein X2 is dA, X14 is Nle, and X28 is Q; a sequence wherein X2 is dA, X14 is Nle, and X28 is K, a sequence wherein X2 is dA, X14 is M, and X28 is Q, a sequence wherein X2 is dA, X14 is M, and X28 is K, a sequence wherein X2 is dA, X14 is Nle, and X28 is N;
a sequence wherein X2 is dA and X39 is selected from any one of C, C(AM), K*, C-PEG, C-PEGC-PEG, C-PEGXaaC-PEG, C-PEGXaaXaaC-PEG, C-PEGXaaXaaXaaC-PEG; a sequence wherein X14 is Nle and X39 is selected from any one of C, C(AM), K*, C-PEG, C-PEGC-PEG, C-PEGXaaC-PEG, C-PEGXaaXaaC-PEG, C-PEGXaaXaaXaaC-PEG, and C-PEGXaaC-PEGXaaC-PEG; a sequence wherein X28 is Q and X39 is selected from any one of C, C(AM), K*, C-PEG, C-PEGC-PEG, C-PEGXaaC-PEG, C-PEGXaaXaaC-PEG, C-PEGXaaXaaXaaC-PEG, and C-PEGXaaC-PEGXaaC-PEG; a sequence wherein X28 is K and X39 is selected from any one of C, C(AM), K*, C-PEG, C-PEGC-PEG, C-PEGXaaC-PEG, C-PEGXaaXaaC-PEG, C-PEGXaaXaaXaaC-PEG, and C-PEGXaaC-PEGXaaC-PEG; a sequence wherein X14 is Nle and X28 is Q and X39 is selected from any one of C, C(AM), K*, C-PEG, C-PEGC-PEG, C-PEGXaaC-PEG, C-PEGXaaXaaC-PEG, C-PEGXaaXaaXaaC-PEG, and C-PEGXaaC-PEGXaaC-PEG; a sequence wherein X14 is Nle and X28 is K and X39 is selected from any one of C, C(AM), K*, C-PEG, C-PEGC-PEG, C-PEGXaaC-PEG, C-PEGXaaXaaC-PEG, C-PEGXaaXaaXaaC-PEG, and C-PEGXaaC-PEGXaaC-PEG; a sequence wherein X2 is dA and X14 is Nle and X39 is selected from any one of C, C(AM), K*, C-PEG, C-PEGC-PEG, C-PEGXaaC-PEG, C-PEGXaaXaaC-PEG, C-PEGXaaXaaXaaC-PEG, and C-PEGXaaC-PEGXaaC-PEG; a sequence wherein X2 is dA, X14 is Nle, and X28 is Q and X39 is selected from any one of C, C(AM), K*, C-PEG, C-PEGC-PEG, C-PEGXaaC-PEG, C-PEGXaaXaaC-PEG, C-PEGXaaXaaXaaC-PEG, and C-PEGXaaC-PEGXaaC-PEG; a sequence wherein X2 is dA, X14 is Nle, and X28 is K and X39 is selected from any one of C, C(AM), K*, C-PEG, C-PEGC-PEG, C-PEGXaaC-PEG, C-PEGXaaXaaC-PEG, C-PEGXaaXaaXaaC-PEG, and C-PEGXaaC-PEGXaaC-PEG, a sequence wherein X2 is dA, X14 is M, and X28 is Q, and X39 is selected from any one of C, C(AM), K*, C-PEG, C-PEGC-PEG, C-PEGXaaC-PEG, C-PEGXaaXaaC-PEG, C-PEGXaaXaaXaaC-PEG, and C-PEGXaaC-PEGXaaC-PEG; a sequence wherein X2 is dA, X14 is M, and X28 is K and X39 is selected from any one of C, C(AM), K*, C-PEG, C-PEGC-PEG, C-PEGXaaC-PEG, C-PEGXaaXaaC-PEG, C-PEGXaaXaaXaaC-PEG, and C-PEGXaaC-PEGXaaC-PEG; a sequence wherein X2 is dA, X14 is Nle, and X28 is N and X39 is selected from any one of C, C(AM), K*, C-PEG, C-PEGC-PEG, C-PEGXaaC-PEG, C-PEGXaaXaaC-PEG, C-PEGXaaXaaXaaC-PEG, and C-PEGXaaC-PEGXaaC-PEG.
The modified amino acid sequence should provide a modified exendin which retains the functional activity and/or enhances certain properties of the unmodified Exentin-4.
According to the present invention, the amino acid sequence of the modified exendin in accordance to the present invention has a higher stability than the non-modified exendin of SEQ ID No. 4. For example, the stability of the amino acid sequence of the modified exendin is at least 5%, at least 10% or at least 20% higher than that of SEQ ID No. 4 measured in % increased purity as described in example 3 or 4 after 15 days.
The stability of the modified exendin can be tested by subjecting the modified exendin to a pH ranging from about 4 to about 8 in a thermostat at 40° C., and determining the purity of the polypeptide by LC-MS as described in more detail in examples 3 and 4. The stability of amino acid sequence of the modified exendin can be expressed as the correlation between the reduction ratio of the main peak area and time, as described in more detail in examples 3 and 4 herein-below.
The present invention also relates to exendins and pharmaceutical acceptable salts thereof derived from single or multiple pegylation at the residue or residues in the C-terminal area of the exendins of SEQ ID Nos. 4 to 141, in which molecular weight of said polyethylene glycol is within the range of 5,000 to 80,000, preferably 20,000 to 60,000. The amino acids of the exendins of the present invention possess critical sites for modification, which include position 2, 14, 27, 28 of the amino acid sequences of exendins.
In an embodiment, the modified exendin may comprise polyethylene glycol with a molecular weight of 20,000-60,000, for example, without limitation, 40,000 daltons, for modification.
In an embodiment, the polyethylene glycol is connected at the regiospecific group at the carboxyl terminal end of the amino acid sequence.
Another objective of the present invention is to provide a method for the preparation of the above-mentioned exendins and pharmaceutical acceptable salts thereof, which includes solid-phase and solution-phase synthesis, purification by reverse-phase high performance liquid chromatography, ion-exchange and gel filtration, and lyophilization.
The present invention also provides the use of the modified exendins or pharmaceutical acceptable salts thereof in accordance with the present invention in treating and/or preventing type II diabetes.
The present invention also discloses a method for the reduction of blood glucose in a mammal, the method comprising administration of an effective amount of the modified exendin or pharmaceutically acceptable salt thereof in accordance with the present invention to the mammal.
Provided is a method for treatment of type 2 diabetes, the method comprising administration of an effective amount of a modified exendin as described herein, or pharmaceutically acceptable salt thereof, to a patient in need thereof.
In an embodiment, said mammal is a human being, preferably the patient in need of the reduction of blood glucose.
Provided is a method for the reduction of blood glucose in a mammal, the method comprising administration of an effective amount of a modified exendin as described herein, or pharmaceutically acceptable salt thereof to the mammal.
DETAILED DESCRIPTION OF THE INVENTIONClinic trials show that when type 2 diabetics, whose blood glucose level was poorly controlled, were subjected to Glucagon-like peptide 1 (GLP-1) treatment, their fasting blood glucose level become normal (Gutniak, et al., New Eng. J. Med. 326:1316-1322, 1992). Long term administration of Glucagon-like peptide 1 (GLP-1) can restore the functions of β-cell to normal level (Rachman, et al., Diabetes 45:1524-1530, 1996). Glucagon-like peptide 1 (GLP-1) can restore the glucose-response function of β-cell in those patients having functional imperfection of glucose tolerance (Byrne, et al., Diabetes 47:1259-1265, 1998). Since Glucagon-like peptide 1 (GLP-1) is readily inactivated by dipeptidyl peptidase (DPP IV) in vivo and many cleavage-points for other endopeptidase (NEP24.11) are present in the Glucagon-like peptide 1 (GLP-1), the in vivo lasting time of Glucagon-like peptide 1 (GLP-1) is very short. Promising therapeutic effects of Glucagon-like peptide 1 can be achieved only by means of continuous administration. In this regard, researchers focus on the development of a more stable Glucagon-like peptide 1 (GLP-1) receptor agonist, mainly formed as modified Glucagon-like peptide 1 (GLP-1). More importantly, in the late 1980s and the early 1990s, Eng et al. isolated Exendin-4 from the saliva secretion organs of the Gila monster (Heloderma Sespectrum) in southwestern. America (Eng, J. et al., J. Biol. Chem., 265:20259-62, 1990, Eng, J., et al. J. Biol. Chem., 267:7402-05, 1992). Exendin-4 is a polypeptide having 39 amino acids, which shows 53% homology with Glucagon-like peptide 1 (GLP-1). Exendin-4 shows affinity to GLP-1 receptor, and it possesses stronger ability than GLP-1. Its ability in adjusting glucose metabolism is better than GLP-1; its minimum concentration for the stimulation of insulin secretion is lower than GLP-1; and more importantly, the in vivo half-life of Exendin-4 is longer than that of GLP-1 (Kudsen, L. B. J. Med. Chem. 47:4128-4134, 2004). These are mainly due to the unique enzymatic stability of Exendin-4, which is originated from the elimination of the cleavage-sites of endopeptidase (such as NEP24.11).
Compounds which possess the function of Glucagon-like peptide 1 (GLP-1) receptor agonist, such as GLP-1 (7-36), GLP-1 (7-37), Exendin-4 and other derivatives of GLP-1 and Exendin-4, have been widely reported in many publications, which include WO98/43658, WO00/15224, WO00/66629, WO01/98331, WO01/04156, U.S. Pat. No. 5,545,618, U.S. Pat. No. 5,118,666, WO03/058203, U.S. patent Application Ser. No. 60/395,738, WO04/022004 and their references cited therein.
Naturally existing GLP-1 receptor agonists are provided in the following table:
Abbreviation in the above sequences: H (His) histidine, A (Ala) alanine, E (Glu) glutamic acid, G (Gly) glycin, T (Thr) threonine, F (Phe) phenylalanine, S (Ser) serine, D (Asp) aspartic acid, V (Val) valine, Y (Tyr) tyrosine, L (Leu) leucine, Q (Gln) glutamine, K (Lys) lysine, I (Ile) isoleucine, R (Arg) arginine, M (Met) methionine, N (Asn) asparagine, P (Pro) proline.
Although more stable GLP-1 receptor agonists have been developed in many laboratories, their in vivo lasting time is still short, and thereby development of long-lasting derivatives of exendins acting as GLP-1 receptor agonists is in great demand. Since the window for the therapeutic effect and side effect (vomit and nausea) is relatively narrower, the use of sustained release formulation affords only a small chance of success. The only possible way to obtain a long-lasting GLP-1 receptor agonist is to prepare a stable compound having sufficiently long in vivo retention time.
Incorporation of polyethylene glycol into active protein or polypeptide increases the retention time of active protein and polypeptide. This technology has been successfully applied in many protein-based biological drugs, such as PEG-Intron, PEGASYS, Neulasta and Somavert and the like. The methods and chemistry for the incorporation of polyethylene glycol into protein and peptide backbone are provided in relevant references, such as the review by Veronese (Veronese, FM, Biomaterial 2001 22:405-417). In view of the fact that both GLP-1 and Exendin-4 belong to GLP-1 receptor, U.S. Pat. No. 5,424,286 and PCT WO98/05351 disclose the comparative experiments of GLP-1 and Exendin-4 in terms of their in vivo insulinotropic secretion function. The experiments showed that Exendin-4 exhibited a stronger and longer in vivo effect than GLP-1 due to its higher stability against the peptidase in vivo (DPP IV, NEP24.11 and the like). PCT WO2004/022004 discloses the pegylated GLP-1 receptor agonist, and proposes that when polyethylene glycol with molecular weight more than 30,000 daltons is employed, side effects, such as nausea and vomit, caused by the activation of the intracephalic GLP-1 receptor, are unlikely to occur with the resulting derivatives. It indicates that pegylated GLP-1 receptor agonist does not only prolong the in vivo acting time, but also minimize its side effects. However, this type of compounds show no improvement in the in vivo enzymatic and chemical stability of their polypeptide backbone in addition to the limitation in their in vivo or in vitro activity, which limits this type of compound acting as desired long-lasting therapeutic agent. The reduced in vivo and in vitro activity may increase the production cost of long-lasting therapeutic agent. In view of the above reasons, using Exendin-4 backbone as the precursor in pegylation may afford a greater chance of success in preparing long-lasting therapeutic agent, in which the polypeptide backbone possesses better enzymatic stability. Although PCT WO00/66629 discloses the resulting compounds and methods involving Exendin-4 as the precursor in pegylation, there is still a long way to go for a successful preparation of a long-lasting therapeutic agent with low production cost. It is because cleavage is likely to occur to His-Gly residue at the N-terminal by dipeptidyl peptidase (such as DPP IV), which renders the GLP-1 receptor agonist inactive no matter that Exendin-4 is able to prolong the in vivo retention time from a few hours to several dozen of hours, or even longer. Meanwhile, the long-lasting pegylated GLP-1 receptor agonist should have good chemical stability, especially at the in vivo temperature, i.e., 37° C., which is highly required for Exdendin-4, of which the methionine residue at position 14 of Exendin-4 backbone is readily undergone oxidation giving rise to the change of its biological activity, by which preparation of therapeutic agent is made troublesome; and furthermore, hydrolysis of the asparagine residue at position 28 is the major cause for the inactivation of therapeutic agent as well as the preparation problem, the mechanism of hydrolysis is shown as below:
From the mechanism, it shows that hydrolysis of the five-membered ring derived from asparagine does not only decrease the activity of GLP-1 receptor agonist, but also cause to the separation of polyethylene glycol from the polypeptide backbone, and thereby adversely effect the retention time in vivo of the long-lasting compound. Accordingly, modification on glycine at position 2 enhances the enzymatic and chemical stability of the Exendin-4 polypeptide backbone; and modifications on methionine at position 14 and on asparagine at position 28 enhance the chemical stability of Exendin-4 polypeptide backbone as well. PCT WO00/66629 emphasizes on the preparation of polyethylene glycol conjugate via acylation with the amino group of the lysine side chain incorporated during pegylation of Exendin-4. Since Exendin-4 itself possesses lysine, selectivity of the acylation reaction is only achievable with suitable use of protecting groups, and thus renders the production with higher cost. By locating the connection point between the polyethylene glycol for modification and the regiospecific group at the carboxyl terminal (C-terminal) of the polypeptide, interaction between the polypeptide and the receptor would not be affected by the polyethylene glycol, whereas a regiospecific reaction can be achieved, and thereby lowers the production cost.
The present invention discloses a series of pegylated derivatives of Exendin-4 modified at position 2, 14, 27, or 28. These pegylated exendins exhibit long-lasting effect in vivo, which can be formulated as long-lasting therapeutic agent for injection use.
The exendins of the present invention induce the activation in vivo and in vitro of the GLP-1 receptor which locates on the surface of β-cell, which further induce the secretion of insulin and thereby lowers the blood glucose level. Examples of the exendins include, but not limited to, the polypeptide sequences in table 12 as well as their pegylated derivatives. Serine at position 39, where pegylation takes place, can be substituted with cysteine or other mercapto-containing synthetic amino acid. Similarly, multiple pegylations can be achieved in the following way, in which two or more mercapto-containing amino acids (such as cysteine) are added to the carboxyl terminal, and the resulting elongated polypeptides derivatives may serve as the pegylation precursor. The general formula for the precursor of two-site modification is Cys(39)-(Xaa)n−1-Cys(n+39), wherein n=0-10, Xaa is any one of the amino acids, and n is the number of amino acids added to the C-terminal end.
The above-mentioned polypeptides can be prepared by chemical synthetic methods, which include liquid-phase synthesis of fragment, solid-phase synthesis (see Merrifield, J. Am. Chem. Soc. 1963, 85:2149-2154), or combined method of solid-phase and liquid-phase; polypeptide synthesis can be conducted manually or automatically. Applied Biosystems 431A polypeptide synthesizer, Csbio polypeptide synthesizer and the like can be employed in automatic synthesis; and also combinatorial synthesis can be used in polypeptide synthesis.
Purification by preparative HPLC is required for the polypeptides prepared by chemical synthetic method, reveres phase materials are commonly used as the column packing materials (such as C4, or C8, or C18). In vivo and in vitro studies of the therapeutic effectiveness are only allowed after characterizations with analytical identifications (such as high performance liquid chromatography (HPLC), mass spectroscopy (MS), amino acids analysis (AAA)). After purification by preparative HPLC, products can be obtained after lyophilization
Polyethylene glycol can be purchased from a variety of suppliers or synthesized by common methods. Molecular weight of polyethylene glycol is usually within the range of 5,000-80,000 daltons, preferably 20,000-60,000 daltons and more preferably about 40,000 daltons.
Polyethylene glycol should be connected with polypeptide at the C-terminal end of the polypeptide in order to minimize the interferences caused by the polyethylene glycol to the action between polypeptide and the receptor. That is to say, polyethylene glycol may connect to any residues locating between positions 29 to 39, which involves substitutions of any one or any few of the amino acids with mercapto-containing amino acid (such as cysteine). In the case of single site pegylation, it is better to substitute serine locating at position 39, carboxyl terminal with cysteine; similarly, in the case of two-site modification, the best way is to substitute serine at position 39 with cysteine and add another cysteine at position 40 or 39+n (n=1-10).
The method for bonding polyethylene glycol via cysteine or mercapto are widely described in many publications (see Veronese, Biomaterials 2001, 22:405-417).
Skilled person in the art can link polyethylene glycol with mercapto-containing exendins.
Particularly, bonding polyethylene glycol via mercapto group can be achieved by way of the following:
1) Mercapto group originates from polypeptide chain. Achieved by incorporating the undermentioned amino acid:
By this time, polyethylene glycol should possess Michael addition acceptor, such as the double bond of maleimide, halogen or sulfonic acid esters substituted groups. Bonding is achieved by forming a thioether bond between polypeptide and polyethylene glycol.
2) Mercapto group originates from the side chain of the amino acid of a modified polypeptide, for example, mercapto group connects with the amino group of the lysine side chain. The amino acid with its side chain modified in the form of the following formula:
By this time, polyethylene glycol should possess Michael addition acceptor, such as the double bond in maleimide, halogen and sulfonic acid esters substituted groups; bonding is achieved by forming a thioether bond between polypeptide and polyethylene glycol.
3) Mercapto group originates from polyethylene glycol. By this time, the connection point in the polypeptide should contain Michael addition acceptor, such as the double bond in maleimide, halogen and sulfonate substituted groups. Bonding is achieved by forming a thioether bond between polypeptide and polyethylene glycol.
4) If both polyethylene glycol and polypeptide contain Mercapto groups, bonding can be achieved via the formation of asymmetric disulfide bond.
Preferably, covalent bond between polyethylene glycol and polypeptide of the present invention is achieved by the formation of a thioether bond in between. However, it is not the only way to link polyethyelene glycol with the polypeptide sequence disclosed in the present invention. Other connection methods, such as acylation, reductive amination and oxime formation, are also included in the present invention.
The polypeptide derivatives listed in table 12 are suitable precursors for pegylation. However, they are included in the present invention by way of illustration only and the present invention is not limited to these sequences. In the sequence table, preferred sequences are selected from SEQ ID NO 87-99, 100-113, 128-141
These pegylated exendins and polypeptide precursors thereof are amphoteric compounds, which can react with acids or bases to form salts. Commonly employed acids for salt formation are selected from hydrochloric acid, hydrobromic acid, hydriodic acid, sulfuric acid, phosphoric acid, p-toluenesulfonic acid, methanesulfonic acid, oxalic acid, p-bromobenzene sulfonic acid, carbonic acid, succinic acid, citric acid, benzoic acid, acetic acid, trifluoroacetic acid and the like. Examples of these salts include sulfate, pyrosulfate, hydrosulfate, sulfite, bisulphite, phosphate, hydrophosphate, dihydric phosphate, metaphosphate, pyrophosphate, hydrochloride, hydrobromide, hydriodate, acetate, propionate, caprate, caprylate, acrylate, formiate, isobutyrate, caproate, heptylate, propiolate, oxalate, malonate, succinate, suberate, sebacate, fumarate, maleate, butyne-1,4-dioate, hexyne-1,6-dioate, benzoate, chlorobenzoate, p-methylbenzoate, dinitrobenzoate, hydroxybenzoate, methoxybenzoate, phenylacetate, phenylpropionate, phenylbutyrate, citrate, lactate, r-hydroxybutyrate, glycerate, tartarate, methanesulfonate, propanesulfonate, naphthalene-1-sulfonate, naphthalene-2-sulfonate, mandelate and the like. Preferred acid addition salt is selected from hydrochloride, sulfate, acetate, trifluoroacetate; commonly employed bases for salt formation are selected from sodium hydroxide, potassium hydroxide, ammonia, potassium carbonate and the like.
The exendins of the present invention, particularly the pegylated exendins, can be used in preventing and treating type 2 diabetes, especially to those patients who present abnormal secretion caused by overweight or even obesity, due to their potential in recovering the β-cell.
Accordingly, the present invention also relates a method for the treatment and prevention of type 2 diabetes, wherein effective dosage of the exendins of the present invention is administered to patients who in need thereof.
The exendins of the present invention can be used alone, and more suitably used in combination with other anti-diabetic medicaments (such as PPAR agonist, sulphonylurea, non-sulphonylurea (Secretagogues), α-glucosidase inhibitor, insulin sensitizer, insulin Secretagogues, glycogen-releasing inhibitor, insulin and other anti-obesity medicaments) in the treatment of diabetes.
Clinical dosage should be determined according to the actual therapeutic effectiveness of the various compounds, which is in the range of 0.0001 mg/kg to about 200 mg/kg body weight, preferably from 0.001 mg/kg to 20 mg/kg body weight, most preferably from 0.01 mg/kg to 1 mg/kg body weight. Routes of administration include injection (including intravenous, intramuscular and subcutaneous injection) or infusion.
These compounds can be formulated in a variety of preparations, and administered by conventional routes of administration, such as oral and transdermal administration, pulmonary, nasal, buccal spray, suppository administration and the like. For example, the modified exendin of the present invention may be formulated into suitable dosage formations by conventional techniques, such as described in Remington's Pharmaceutical Sciences, 18th Ed., 1990. In one embodiment, the modified exendin of the present invention may be formulated into an injectable formation under sterile conditions with suitable agents, including but not limited to a medium, such as injection water, a preservative, such as m-Cresol, suitable buffering agent, such as acetic acid and sodium acetate, etc.
The examples provided hereinafter assist in better understanding the present invention, which are not intended to limit the present invention.
Example 1 Solid-Phase Synthesis of Compound SEQ ID No 95 of the Present Invention
- (1) Amino Acid Monomers Used in the Synthesis
Fmoc-His(Trt)-OH, Fmoc-dAla-OH, Fmoc-Gly-OH, Fmoc-Glu(OtBu)-OH, Fmoc-Thr(tBu)-OH, Fmoc-Phe-OH, Fmoc-Ser(tBu)-OH, Fmoc-Asp(OtBu)-OH, Fmoc-Leu-OH, Fmoc-Lys(Boc)-OH, Fmoc-Gln(Trt)-OH, Fmoc-Nle-OH, Fmoc-Ala-OH, Fmoc-Val-OH, Fmoc-Arg (pbf)-OH, Fmoc-Ile-OH, Fmoc-Trp(Boc)-OH, Fmoc-Asn(Trt)-OH□Fmoc-Pro-OH□Fmoc-Cys(Trt)-OH
Abbreviation of the above: Fmoc: 9-fluorenylmethoxycarbonyl; Boc: tert-butoxycarbonyl; Trt: trityl; OtBu: t-butoxy; tBu: t-butyl. - (2) The Reagents used: N,N-diisopropylethylamine, diisopropylcarbodiimide (DIC), N,N-dimethylformamide (DMF), dichloromethane, hexahydropyridine, 1-hydroxybenzotriazole, Rink amide resin, ninhydrin, methanol, anisole, triisopropylsilane, trifluoroacetic acid.
- (3) Experimental procedure
- A. Synthesis: To 0.5 g (0.25 mmole) Rink amide resin in a reactor vessel, 1 mmol amino acid was added, activation was conducted with DIC/HOBT method, and the synthesis was conducted starting from C-terminal to N-terminal according to the polypeptide sequence. The reaction was conducted at 25° C. (room temperature) following the operating procedure below:
- 1. Fmoc group was deprotected twice by treating with 20% hexahydropyridine in DMF, 10 min for each time.
- 2. The resins were washed with 10 mL DMF for three times, and then dried with pump.
- 3. The protected amino acid (1 mmol) and HOBT (1 mmol) were weighed out and then dissolved in 10 ml DMF followed by addition of DIC (1 mmol), and then activated for 10 minutes.
- 4. The activated amino acid solution was added to the reactor vessel and then shaked for 1 hour.
- 5. The resins were washed with DMF for three times, and then dried with pump.
- 6. Steps 1-5 were repeated for the next cycle in the case of negative result for the ninhydrin test, whereas steps 3-5 were repeated in the case of positive result for the ninhydrin test.
- After the synthesis of polypeptides, the resins were completely washed with methanol and then dried in air.
- B. Deprotection of the protecting groups and cleavage of polypeptides
- To 1 g resin having the polypeptide in the reactor vessel was added the cleavage solution in the following proportion.
- A. Synthesis: To 0.5 g (0.25 mmole) Rink amide resin in a reactor vessel, 1 mmol amino acid was added, activation was conducted with DIC/HOBT method, and the synthesis was conducted starting from C-terminal to N-terminal according to the polypeptide sequence. The reaction was conducted at 25° C. (room temperature) following the operating procedure below:
-
- The content in reactor vessel was shaked for 2 hours at room temperature, and then filtered. The filtrate was collected and the resins were washed with a slight amount of acetic acid. The collection fluids were combined. After concentration, ethylether was added and precipitate was generated. Precipitate was washed with a slight amount of ethylether to afford the crude product.
- C. Purification with high performance liquid chromatography and lyophilization
- The resulting crude product was dissolved in 10% acetic acid solution, the solution was injected into the HPLC system for purification, followed by lyophilization to afford the product. The resulting polypeptide was analyzed and confirmed as the desired compound using Chromatography-Mass Spectrometry.
- Column: 1 una C18 (2), 5μ, 100 Å
- Detective wavelength: λ=220 nm, Waters preparative system
- Gradient: (TFA: trifluoroacetic acid)
-
- The molecular weight of the resulting compound: 4212.6 g/mol; the theoretical molecular weight: 4213 g/mol.
FIG. 1 : LC-MS spectrum of SEQ ID No: 95.
- The molecular weight of the resulting compound: 4212.6 g/mol; the theoretical molecular weight: 4213 g/mol.
Pegylation of exendins can be conducted with conventional method. Pegylation of peptides is achieved by modifying mercapto group in the formation of a thioether bond between polyethylene glycol and peptide. To be more particular, one or more cysteines were added to the carboxyl-terminal of the optimized Exendin-4 derivatives, followed by pegylation conducted by using polyethylene glycol which contains the Maleimide functional group. Thioether bond was formed after Michael addition reaction, and thereby polypeptide was covalently bonded with the polyethylene glycol. In general, the desired polypeptide was dissolved in 0.1M phosphate buffer solution, followed by addition of polyethylene glycol under anaerobic environment. The molar ratio of polyethylene glycol to polypeptide was 1:1 and the pH of the reaction was 6 to 7.5. Oxidation of the mercapto group may be reduced by addition of EDTA to the reaction solution. After two hours, the reaction solution was purified with reverse-phase HPLC system. Excess or unreacted polyethylene glycol was removed by ion-exchange chromatography. The molecular weight of the resulting product was analyzed and confirmed by mass spectrum. The purity of the product was analyzed with RP-HPLC and Gel-chromatography. Taking the modification of SEQ ID NO 95 as an example, when 40 KD PEG was employed in modification, the yield was 70-90% (based on polyethylene glycol).
Example 3 Test for the Stability of the PolypeptideThe Exendin-4 derivatives of the present invention possess the optimized enzymatic and chemical stability. The following method was used to determine the chemical stability of some polypeptides in the present invention.
1 mg of each sample was dissolved in a buffer solution, which contains 150 mM sodium chloride and 20 mM phosphate, from which a solution of concentration of 4 mg/ml was prepared and its pH is 8.0. The testing sample solutions were placed in a thermostat of 40° C. LC-MS was used to determine the purity of polypeptide. Correlation between the reduction ratio of the main peak area and time reflects the chemical stability of the polypeptide. Expressed as a percentage, purity is the percentage corresponding to the target peak in the total of all peaks including impurities. Using LC, the main peak was separated from any impurities, and the relative percentages of main peak and impurities at times 0 (before incubation at 40° C. at pH 4.5-8) and after 5, 10 and 15 days were determined. MS was used to identify the main peak as the target molecule. The main peak area plus the peak areas of any impurities gives a total equal to 100%, with relative purity calculated at a certain time (5, 10 or 15 days) against the purity at time 0 compared to the purity before incubation at 40° C. at pH 4.5-8.
Sample 1 is Exendin-4 as control, and the sequence is:
Sample 2: 2# Gly in sample 1 was substituted with d-Ala, and 39# was substituted with Cys.
Sample 3: 2# Gly in sample 1 was substituted with d-Ala, and 14# Met was substituted with Nle, 28# Asn was substituted with Gln.
Sample 4: sample 2 is covalently bonded with PEG40K via Cys at the C-terminal end of sample 2; wherein all the C-terminal ends of samples 1-4 are amide.
Conclusion:
The sequence of sample 1 is a polypeptide sequence that can be isolated from nature. His-Gly residue at the N-terminal end is an ideal substrate for dipeptidase and Met that contained in sample 1 readily undergoes oxidization, and also Asn undergoes self-reaction readily, which render sample 1 unstable. Substitution at position 2, or 14, or 28 greatly improve the stability of the peptides; in addition, substitution at all the 3 positions allows a greater improvement in the stability of the peptides than substitution of His-Gly with His-dAla alone. Although sample 2 is not very stable, it become very stable after bonding with PEG40K (i.e. sample 4), which shows that PEG is useful in enhancing the stability of polypeptide.
Example 4 Stability of Exendin-4 Derivatives Under Acidic/Basic ConditionsThe following method was used to determine the chemical stability of various modified exendins having a sequence identity of at least 90% to SEQ ID no. 17 under acidic/basic conditions. All modified exendin sequences show increased stability, having an increased relative purity of at least 5% higher than the control (unmodified exendin of SEQ ID No. 4) after 15 days when exposed to 40° C. at pH 4.5-8. Purity was determined by LC-MS as percentage of the target peak in the total of all peaks including impurities as described in example 3.
1. Acidic Conditions:
4 mg Exendin-4 derivative polypeptide (described in Table 2 below) was dissolved in 20 mM sodium buffer (pH 4.5) so as to prepare a solution at concentration of 4 mg/ml. The testing sample solutions were placed in a thermostat setting at 40° C. LC-MS was used to determine the purity of polypeptide. The chemical stability of the polypeptide was expressed as the correlation between the reduction ratio of the main peak area and time and determined as described above. The results were listed in the following Table 3.
2. Basic Conditions:
4 mg Exendin-4 derivative polypeptide (described in Table 3 above) was taken and dissolved in PBS buffer (KH2PO4 0.27 g/L, Na2HPO4 1.42 g/L, NaCl 8 g/L and KCl 0.2 g/L, pH 7.4) so as to prepare a solution at concentration of 4 mg/ml. The testing sample solutions were placed in a thermostat setting at 40° C. LC-MS was used to determine the purity of polypeptide. The chemical stability of the polypeptide was expressed as the correlation between the reduction ratio of the main peak area and time. The results were illustrated in the following Table 4.
From the data listed in Tables 3 and 4, the Exendin-4 derivative polypeptides with substitution at position 2, 14 and/or 28 according to the present application have improved stability as compared with the parent polypeptide of Exendin-4 (SEQ ID No: 4). It can be seen that the stabilities of samples 3, 6˜7 and 9˜13, the substitution at two or more positions allows yields a greater improvement in the stability of the peptides than substitution of His-Gly with His-dAla alone. Those results are consistent with the data shown in Example 3 above, demonstrating that the substitutions of the amino acids at the key points increased the stability of Exendin-4 peptide backbone.
In samples 2-1 and 9-1 which have cysteine at C-terminal end, the main impurity was dimers formed by oxidization of the mercapto-groups. Samples 4 and 13 with PEG40K covalently linked with Cys at the C-terminal end have even higher stability than samples 2-1 and 9-1, showing that PEG modification has significant effects on the improvement of polypeptide stability.
Experimental Example 1 Oral Glucose Tolerance Test of PEG-EXENDIN-4 (PEG-EX-4) AnaloguePolypeptide of SEQ ID NO: 25 was modified with polyethylene glycol of molecular weight of about 40,000 (sample 4 as described in Examples 3 and 4 above). Oral glucose tolerance test was then conducted with normal mice and the results were presented in the following tables:
1. Testing animals: species, strains: db/db mice, source: Model Animal Center of Nanjing University, body weights of mice: 35 g-50 g, male and female in half. Numbers of animal: 45, 5-6 mice in each group. Rearing conditions: rearing in SPF grade animal housing, temperature: 22° C.-24° C., humidity: 45%-80%, illumination: 150 Lx-300 Lx, under the 12 h-light and 12 h-dark cycle condition.
2. Test method:
Dosage setting up: 5 administration groups: 0.03, 0.1, 0.3, 1 and 3 mg/kg; and a blank control group as well; route of administration: subcutaneous injection; volume of administration: 0.05 ml/kg body weight.
(1) Influence on Blood Glucose Level of Non-Fasting db/db Mice
According to the non-fasting blood glucose level and body weight of mice, db/db mice were divided into blank control group and another 5 groups to be administered with PEG-EX-4 analogue, 6 mice in each group, and male and female in half. Animals in each group were administered with the testing drug and physiological saline, respectively, by a single subcutaneous injection. Blood glucose level was detected before administration and also 1, 2, 4, 8, 24 hours after administration. Thereafter, the non-fasting blood glucose level was detected every 24 hours. The lasting time for the reduction of blood glucose level of the testing drugs as well as the variation in food intake and body weights after administration were observed.
(2) Influence on Blood Glucose Level of Fasting db/db Mice
According to the non-fasting, fasting blood glucose level and body weight of mice, db/db mice were divided into blank control group and another 5 groups to be administered with PEG-EX-4 analogue, 6 mice in each group, and male and female in half. After fasting for 5 hours, animals in each group were administered with the testing drug and physiological saline, respectively, by a single subcutaneous injection. Blood glucose level was detected before administration and also 1, 2 hours after administration. Thereafter, the non-fasting and fasting blood glucose level was detected every 24 hours. The lasting time for the reduction of blood glucose level of the testing drug as well as the variation in food intake and body weights after administration were observed.
(3) Influence on Fasting Blood Glucose Level of db/db Mice
According to the fasting blood glucose level and body weight of mice, db/db mice were divided into blank control group and another 5 groups to be administered with PEG-EX-4 analogue, and 5 mice in each group. After fasting for 5 hours, animals in each group were administered with the testing drug and physiological saline, respectively, by a single subcutaneous injection. 2.5 g/kg of glucose was taken orally 15 minutes after the above administration. After that, blood glucose level was detected immediately after taking glucose (0 min) and also 30, 60 and 120 minutes after taking glucose. Oral glucose tolerance test was conducted on the third day, sixth day and ninth day, respectively, after the drug administration. The influences of the testing drug on the glucose tolerance of db/db as well as its lasting time and the variation in food intake and body weights after administration were observed.
3. Test results: the results for the influences of PEG-EX-4 analogue on blood glucose level of db/db mice were presented and summarized in
(1) Influence on Blood Glucose Level of Fasting and Non-Fasting db/db Mice
(2) Influence on Fasting Blood Glucose Level of db/db Mice
1. Test Methods:
Single subcutaneous injections of PEG-EX-4 analogue at various dosages were administered to normal mice. Variation in blood glucose level at different times after injection was detected.
2. Test Results:
(1) See
(2) See
In table 7, C, hC, K* are the modification sites for pegylation. C is cysteine, hC is homocysteine and K* is lysine with a modified side-chain, such as the mercaptopropionic acid on the amino group of the side chain of lysine. CC, hChC or K*K* in the sequence represent two modification sites for pegylation. Nle is norleucine, dA is D-alanine, —NH2 is an amide at the C-terminal end.
Claims
1. A modified exendin or pharmaceutically acceptable salt thereof, comprising an amino acid sequence having at least 90% sequence identity to SEQ ID No. 17, wherein the amino acid in the position of said amino acid sequence corresponding to position 2 of SEQ ID No. 17 is D-Ala, wherein one or both amino acids in the positions of said amino acid sequence corresponding to positions 14 and 28 of SEQ ID No. 17 are substituted to be other than Met in position 14 and/or Asn at position 28, wherein each said position refers to the position as numbered in SEQ ID No. 17, and wherein the modified exendin or salt thereof has a higher stability than the non-modified exendin of SEQ ID No. 4, and wherein the amino acid sequence is SEQ ID No. 94.
2. The modified exendin of claim 1 further comprising polyethylene glycol with a molecular weight of 20,000 to 60,000 daltons for modification.
3. The modified exendin of claim 2, wherein the polyethylene glycol is connected to a regiospecific group at the carboxyl terminal end of the amino acid sequence of the modified exendin.
4. A method for treatment of type 2 diabetes, the method comprising administration of an effective amount of a modified exendin or pharmaceutically acceptable salt thereof according to claim 1 to a patient in need thereof.
5. The method of claim 4, further comprising polyethylene glycol with a molecular weight of 20,000 to 60,000 daltons for modification.
6. The method of claim 5, wherein the polyethylene glycol is connected to a regiospecific group at the carboxyl terminal end of the amino acid sequence of the modified exendin.
7. A method for the reduction of blood glucose in a mammal, the method comprising administration of an effective amount therefor of a modified exendin or pharmaceutically acceptable salt thereof according to claim 1 to the mammal.
8. The method of claim 7, wherein the modified exendin further comprises polyethylene glycol with a molecular weight of 20,000 to 60,000 daltons connected at the regiospecific group at the carboxyl terminal end of the amino acid sequence for modification.
6329336 | December 11, 2001 | Bridon et al. |
6767887 | July 27, 2004 | Hoffmann et al. |
6872700 | March 29, 2005 | Young et al. |
6969702 | November 29, 2005 | Bertilsson et al. |
20040029784 | February 12, 2004 | Hathaway |
WO 00/66629 | April 2000 | WO |
00 66629 | November 2000 | WO |
01 04156 | January 2001 | WO |
2004 022004 | March 2004 | WO |
- Eng, 1992, Journal of Biological Chemistry, vol. 267, pp. 7402-7405.
- Pasquo, 2012, PLoS ONE, vol. 7, Issue 2, e32555.
- Al-Sabah, 2002, Astbury Centre for Structural Molecular Biology, University of Leeds, Annual report, pp. i-viii and 17-19.
- Al-Sabah, 2003, British Journal of Pharmacology, vol. 140, pp. 339-346.
- Al-Sabah, 2004, Protein and Peptide Letters, vol. 11, No. 1, pp. 9-14.
- Xiao, 2001, Biochemistry, vol. 40, pp. 2860-2869.
- Tsubery H. et al.; “Prolonging the Action of Protein and Peptide Drugs by a Novel Approach of Reversible Polyethylene Glycol Modification”; J. Biol. Chem, vol. 279, No. 37, Sep. 10, 2004, pp. 38118-38124.
- Eng J et al.; “Isolation and Characterization of Exendin-4, an Exendin-3 Analogue, from Heloderma suspectrum Venom”, J. Biol. Chem, vol. 267, No. 11 Apr. 15, 1992, pp. 7402-7405.
- Michael A.N. et al.; “Glucagon-like peptide 1 and its derivatives in the treatment of diabetes”; Regulatory Peptides, vol. 128, Sep. 8, 2004, pp. 135-148.
Type: Grant
Filed: Dec 22, 2011
Date of Patent: May 6, 2014
Patent Publication Number: 20120196802
Assignee: Wuxi Grandchamp Pharmaceutical Technology Co., Ltd. (Jiangsu)
Inventors: Aifeng Lv (Jiangsu), Changan Sun (Jiangsu), Yali Wang (Jiangsu)
Primary Examiner: Robert Landsman
Assistant Examiner: Ian Dang
Application Number: 13/334,912
International Classification: A61K 38/00 (20060101); A61K 38/26 (20060101);